Scientific and Technical Problems in Heat-And-Power Engineering and Heat Technology

Baidildina Aizhan

The instructor profile

Description: The discipline covers modern problems of energy, the use of fuel and energy resources, types, methods of their production and transformation. Considerable attention is paid to household energy saving, energy saving and ecology, energy saving technologies in thermal power engineering and thermal technology, as well as in industry.

Amount of credits: 5

Пререквизиты:

  • Kinetic Theory of Heat Technology Phenomena

Course Workload:

Types of classes hours
Lectures 30
Practical works 15
Laboratory works
SAWTG (Student Autonomous Work under Teacher Guidance) 30
SAW (Student autonomous work) 75
Form of final control Exam
Final assessment method

Component: University component

Cycle: Profiling disciplines

Goal
  • The purpose of the course is to prepare the undergraduate to solve the problems of designing, researching and operating heat and power and heat technology installations and systems, analyzing the efficiency of energy conversion schemes, evaluating the prospects of new methods of energy production, and introducing innovative developmen
Objective
  • preparation of undergraduates for the dissertation, for the development skills in choosing the optimal solution for the set scientific and technical tasks, the ability to navigate in information and reference literature
Learning outcome: knowledge and understanding
  • Apply the prospects of scientific and technical development, achievements of science and technology, advanced domestic and foreign experience in the field of thermal power engineering
Learning outcome: applying knowledge and understanding
  • analyze the processes occurring in heat engineering installations and summarize the results obtained
Learning outcome: formation of judgments
  • the main problems and directions of scientific and technological progress in heat power engineering and heat engineering
Learning outcome: communicative abilities
  • to use scientific methods of cognition for the study of processes, installations and systems of thermal power engineering and thermal technology
Learning outcome: learning skills or learning abilities
  • Possess modeling methods involving computer technologies for calculating energy use systems
Teaching methods

Study of the theory in conjunction with the equipment used in thermal power plants

Assessment of the student's knowledge

Teacher oversees various tasks related to ongoing assessment and determines students' current performance twice during each academic period. Ratings 1 and 2 are formulated based on the outcomes of this ongoing assessment. The student's learning achievements are assessed using a 100-point scale, and the final grades P1 and P2 are calculated as the average of their ongoing performance evaluations. The teacher evaluates the student's work throughout the academic period in alignment with the assignment submission schedule for the discipline. The assessment system may incorporate a mix of written and oral, group and individual formats.

Period Type of task Total
1  rating Renewable energy sources 0-100
Convective heat transfer
Fuel combustion systems
Oral survey
Midterm control 1
2  rating energy saving 0-100
Locally equilibrium macroparameters of inhomogeneous gases as moments
Phenomena at the gas-solid wall, liquid-solid wall interface
Oral survey
Midterm control 2
Total control Exam 0-100
The evaluating policy of learning outcomes by work type
Type of task 90-100 70-89 50-69 0-49
Excellent Good Satisfactory Unsatisfactory
Know: · physical foundations of reliability analysis of electric power systems; · methods for calculating reliability indicators of electric power systems; · methods for synthesizing electrical power systems and networks at a given level of reliability. Be able to: · calculate indicators of the level of reliability of electric power systems; · synthesize diagrams of electrical power systems according to a given level of reliability; Own: · skills in drawing up design equivalent circuits for calculating reliability indicators of electric power systems and networks. A complete, detailed answer to the question posed is given, the totality of conscious knowledge about the object is shown, the main provisions of the topic are conclusively revealed; the answer shows a clear structure, a logical sequence that reflects the essence of the concepts, theories, and phenomena being revealed. Knowledge about an object is demonstrated against the background of understanding it in the system of a given science and interdisciplinary connections. The answer is stated in literary language in scientific terms. There may be shortcomings in the definition of concepts, which are corrected by the student independently during the answering process. A complete, but insufficiently consistent answer to the question posed is given, but at the same time the ability to identify essential and non-essential features and cause-and-effect relationships is demonstrated. The answer is logical and stated C+ 70-74 in scientific terms. There may be 1-2 mistakes made in defining basic concepts, which the student finds difficult to correct on his own. An incomplete answer was given, representing scattered knowledge on the topic of the question with significant errors in definitions. There is fragmentation and illogical presentation. The student does not realize the connection of this concept, theory, phenomenon with other objects of the discipline. There are no conclusions, specificity and evidence of the presentation. Speech is illiterate. Additional and clarifying questions from the teacher do not lead to correction of the student’s answer not only to the question posed, but also to other questions in the disciplines A complete, detailed answer to the question posed is given, the totality of conscious knowledge about the object is shown, the main provisions of the topic are conclusively revealed; the answer shows a clear structure, a logical sequence that reflects the essence of the concepts, theories, and phenomena being revealed. Knowledge about an object is demonstrated against the background of understanding it in the system of a given science and interdisciplinary connections. The answer is stated in literary language in scientific terms. There may be shortcomings in the definition of concepts, which are corrected by the student independently during the answering process.
Evaluation form

The student's final grade in the course is calculated on a 100 point grading scale, it includes:

  • 40% of the examination result;
  • 60% of current control result.

The final grade is calculated by the formula:

FG = 0,6 MT1+MT2 +0,4E
2

 

Where Midterm 1, Midterm 2are digital equivalents of the grades of Midterm 1 and 2;

E is a digital equivalent of the exam grade.

Final alphabetical grade and its equivalent in points:

The letter grading system for students' academic achievements, corresponding to the numerical equivalent on a four-point scale:

Alphabetical grade Numerical value Points (%) Traditional grade
A 4.0 95-100 Excellent
A- 3.67 90-94
B+ 3.33 85-89 Good
B 3.0 80-84
B- 2.67 75-79
C+ 2.33 70-74
C 2.0 65-69 Satisfactory
C- 1.67 60-64
D+ 1.33 55-59
D 1.0 50-54
FX 0.5 25-49 Unsatisfactory
F 0 0-24
Topics of lectures
  • Special issues of heat and mass transfer
  • Mathematical modeling and numerical methods for solving problems of heat and mass transfer
  • Special questions of the theory of combustion
  • Predictive analysis of energy technologies and structures
  • Current state and promising methods and methods for obtaining and converting thermal and electrical energy
  • Problems and prospects for the development and improvement of the main equipment of power plants and technological schemes
  • Problems and prospects for the development and improvement of methods and methods for the preparation and combustion of fuel, the use of secondary energy resources and industrial waste as an energy fuel
  • Ensuring the reliability of the operation of power equipment
  • Optimization of the development of energy systems and power plants
  • Problems of reconstruction and modernization of heat power equipment of objects and facilities of heat power industry
  • Problems and prospects for the use of non-traditional and renewable energy sources for the energy supply of integrated and autonomous consumers
  • Environmental problems of thermal power engineering
  • Analysis of trends and patterns in the development of the energy sector (globalization, liberalization, diversification, decentralization, modernization)
  • Development of energy policy and mechanisms for its implementation
  • Energy security of the country
Key reading
  • Ушаков В.Я. Современные проблемы электроэнергетики : учебное пособие / Ушаков В.Я.. — Томск : Томский политехнический университет, 2014. — 447 c. — ISBN 978-5-4387-0521-5. — Текст : электронный // IPR SMART : [сайт]. — URL: https://www.iprbookshop.ru/34715.html (дата обращения: 15.09.2023). — Режим доступа: для авторизир. пользователей
  • Мостовенко Л.В. Основы промышленной теплоэнергетики : учебное пособие / Мостовенко Л.В., Белоглазов В.П.. — Нижневартовск : Нижневартовский государственный университет, 2022. — 124 c. — ISBN 978-5-00047-661-1. — Текст : электронный // IPR SMART : [сайт]. — URL: https://www.iprbookshop.ru/129082.html (дата обращения: 15.09.2023). — Режим доступа: для авторизир. пользователей
  • Воронин А.И. Современные проблемы теплогазоснабжения населенных мест и предприятий : учебное пособие (курс лекций) / Воронин А.И.. — Ставрополь : Северо-Кавказский федеральный университет, 2014. — 199 c. — Текст : электронный // IPR SMART : [сайт]. — URL: https://www.iprbookshop.ru/63223.html (дата обращения: 15.09.2023). — Режим доступа: для авторизир. пользователей
Further reading
  • Актуальные проблемы энергетического права : учебник / В.В. Романова [и др.].. — Москва : Юрист, 2015. — 380 c. — ISBN 978-5-91835-271-7. — Текст : электронный // IPR SMART : [сайт]. — URL: https://www.iprbookshop.ru/90161.html (дата обращения: 15.09.2023). — Режим доступа: для авторизир. пользователей